Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I've created all singletons in my program with that document in mind: http://erdani.com/publications/DDJ_Jul_Aug_2004_revised.pdf (in case anyone wondered why singleton, all of them are factories and some of them store some global settings concerning how they should create instances).

Each of them looks somehow like this:

declaration:

class SingletonAndFactory {
    static SingletonAndFactory* volatile instance;

public:
    static SingletonAndFactory& getInstance();

private:
    SingletonAndFactory();

    SingletonAndFactory(
        const SingletonAndFactory& ingletonFactory
    );

    ~SingletonAndFactory();
};

definition:

boost::mutex singletonAndFactoryMutex;

////////////////////////////////////////////////////////////////////////////////

// class SingletonAndFactory {

SingletonAndFactory* volatile singletonAndFactory::instance = 0;

// public:

SingletonAndFactory& SingletonAndFactory::getInstance() {
    // Singleton implemented according to:
    // "C++ and the Perils of Double-Checked Locking".
    if (!instance) {
        boost::mutex::scoped_lock lock(SingletonAndFactoryMutex);
        if (!instance) {
            SingletonAndFactory* volatile tmp = (SingletonAndFactory*) malloc(sizeof(SingletonAndFactory));
            new (tmp) SingletonAndFactory; // placement new
            instance = tmp;
        }
    }
    return *instance;
}

// private:

SingletonAndFactory::SingletonAndFactory() {}

// };

Putting aside question what design of singleton is the best (since it would start a pointless flame war) my question is: would it benefit me to replace normal pointer with std::unique_ptr? In particular, would it call singleton's destructor on program exit? If so how would I achieve it? When I tried to add something like friend class std::unique_ptr<SingletonAndFactory>; it didn't worked out since compiler keep on complaining that the destructor is private.

I know it doesn't matter in my current project since none of factories have something that would require cleaning of any sort, but for future reference I would like to know how to implement such behavior.

share|improve this question
1  
Thing& getThing() { static Thing thing; return thing; } Forget the locks, forget the singletons. –  R. Martinho Fernandes Oct 9 '13 at 13:58
2  
And... seriously? malloc + placement new? Oh, come on... –  R. Martinho Fernandes Oct 9 '13 at 14:00
1  
@R.MartinhoFernandes: If you're going to use singletons, you might as well make them as wrong as possible. There are those who advocate making wrong code look wrong. –  Mike Seymour Oct 9 '13 at 14:04
1  
I also wonder if the pointer is used for memory-mapped I/O, because it is tagged volatile. C++11 assigns no thread-related semantics to volatile. –  R. Martinho Fernandes Oct 9 '13 at 14:06
    
It looks like the volatile was copied from an example in the linked document describing how volatile was not sufficient for thread safety. You need C++11 to provide the necessary atomicity guarantees; and once you've got C++11, you might as well use a local static. –  Mike Seymour Oct 9 '13 at 14:08

2 Answers 2

up vote 3 down vote accepted

It's not the unique_ptr itself that does the deletion, it's the deleter. So if you wanted to go with the friend approach, you'd have to do this:

friend std::unique_ptr<SingletonFactory>::deleter_type;

However, I don't think it's guaranteed that the default deleter will not delegate the actual delete to another function, which would break this.

Instead, you might want to supply your own deleter, perhaps like this:

class SingletonFactory {
    static std::unique_ptr<SingletonFactory, void (*)(SingletonFactory*)> volatile instance;

public:
    static SingletonFactory& getInstance();

private:
    SingletonFactory();

    SingletonFactory(
        const SingletonFactory& ingletonFactory
    );

    ~SingletonFactory();

    void deleter(SingletonFactory *d) { d->~SingletonFactory(); free(d); }
};

And in the creation function:

SingletonFactory* volatile tmp = (SingletonFactory*) malloc(sizeof(SingletonFactory));
new (tmp) SingletonFactory; // placement new
instance = decltype(instance)(tmp, &deleter);
share|improve this answer
    
Thanks! That's the answer that I was looking for. I know that there are several ways to achieve singleton behavior (e.g. silviuardelean.ro/2012/06/05/few-singleton-approaches) and the difference between some of them is just the taste. I was looking for a way to improve my own implementation. Guts of getInstance() can easily be switched to something else and I probably do it some time soon (since I switched to C++11), but I wanted to improve my design as a whole. –  maddening Oct 9 '13 at 14:22
    
@maddening I didn't put it into the answer (because I didn't have time to read the link in your question), but please pay close attention to the comments others have made to your question. A lot of the design decisions in your code (placement new, volatile) are questionable at best. –  Angew Oct 9 '13 at 14:31
    
I am well aware of that. I am currently at the process of finding out how to improve code in my project. It's actually more of a self learning project where I can experiment with things to understand C++ better. I will certainly use some of those advises, though - as for now - singletons will stay. –  maddening Oct 9 '13 at 14:52

In C++11, you can guarantee thread-safe lazy initialisation and destruction at the end of the program using a local static:

SingletonAndFactory& SingletonAndFactory::getInstance() {
    static SingletonAndFactory instance;
    return instance;
}

Beware that this can still cause lifetime issues, as it may be destroyed before other static objects. If they try to access it from their destructors, then you'll be in trouble.

Before that, it was impossible (although the above was guaranteed by many compilers). As described in the document you link to, volatile has nothing to do with thread synchronisation, so your code has a data race and undefined behaviour. Options are:

  • Take the (potentially large) performance hit of locking to check the pointer
  • Use whatever non-portable atomic intrinsics your compiler provides to test the pointer
  • Forget about thread-safe initialisation, and make sure it's initialised before you start your threads
  • Don't use singletons

I favour the last option, since it solves all the other problems introduced by the Singleton anti-pattern.

share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.